Automation of a high-speed continuous casting plant

ABSTRACT

The invention relates to a method for automatically opening a high-speed continuous casting plant According to said method the stopping or slide movement, the modification of the steel level, the heat currents through the mold walls, the temperature of the liquid metal and the drawing-off speed are measured over the casting time, supplied to a computer and compared with predetermined limit values for an automatic operating mode.

CROSS REFERENCE TO RELATED APPLICATION

This application is a 371 of PCT/EP00/05216, filed on Jun. 7, 2000.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a method as well as to a system Particularly for the operation of high-speed plants for slabs and, in this connection, particularly in combination with rolling mills, it is important to be able to operate the continuous casting plant at a high and controlled speed in a safe way.

This necessity of safety for casting particularly at high casting speeds up to 10 m/min. makes it necessary to carry out control of numerous processing data, which are intermeshed in a complex fashion with one another, by means of automation.

This automation must be reduced with respect to its external operation language to a simple functional language which is easily manageable by the operating personnel.

Moreover, the degree of automation, which in regard to its operating language knows only the selection of casting speed and the control all of the narrow side heat flow at the operator (NO) or drive (ND) side, should provide the possibility of operation by autopilot when certain conditions such as

a controlled steel temperature in the distributor

a good oxidic purity of the steel

a calm meniscus as well as

a constant and uniform heat flow of the faces are present.

2. Description of Related Art

The prior art discloses the measuring of the heat flows of all four copper plates of a slab casting mold (DE 4117073) but in this patent document no prior art as a function of the casting speed is disclosed. For example, a speed increase has a minimal effect on the casting mold stress, expressed as MW/m², and a great effect on the strand shell stress expressed as MWh/m².

FIG. 1 shows this correlation and illustrates that at high casting speeds, when using casting powder and a certain castings speed of, for example, >4.5 m/min., the casting mold stress remains almost constant and the strand shell stress is greatly reduced. The reason for this is that at high casting speed a constant slag film and thus a constant heat transfer occurs but a residence time of the strand shell within the casting mold decreases proportionally to the casting speed increase. This illustration makes clear that with increasing casting speed the casting mold stress no longer increases and the casting shell stress decreases so that the risk of fracture formation is reduced but also the casting shell becomes thinner and hotter, for example, at the end of the casting mold.

In FIG. 2, the interrelationships are represented between

casting slag film,

the strand shell temperature, for example, at the exit of the

casting mold, strand shell thickness, and shrinkage,

casting mold and strand shell stresses or shrinkage,

maximum casting mold skin temperature at the meniscus and thus of the casting mold service life in relation to the recrystallization temperature which results in softening of the cold-rolled copper.

U.S. Pat. No. 3,478,808 discloses a method for controlling the parameters of a continuous casting plant for casting steel. Nominal values of parameters, which have been taken from a previous casting process, are stored; actual values of the parameters are recorded, an adjustment of the actual and nominal values is carried out, and a control of the parameters is performed. The disclosed parameters are inter alia the flow speed, the heat removal rate within the casting mold and the removal speed.

SUMMARY OF THE INVENTION

Based on this, it is an object of the invention to further develop a method and a system for performing the method for a controlled operation of a continuous casting plant for casting slab, in particular, thin slab, with very high casting speeds.

An automation of the continuous casting process based on an “online” data acquisition is made possible which enables in addition to

a semi-automation, i.e., the control of the narrow side conicity and the casting speed, also

a full automation in the sense of an autopilot operation with consideration and as a function of the steel temperature in the distributor and with the prerequisite of a controlled

purity,

meniscus, and

face heat flow.

This object is solved by the features of the method claim 1 and the device claim with their dependent claims for configuring the invention.

BRIEF DESCRIPTION OF THE DRAWING

The Figures are provided as examples for illustrating the invention and are described in the following. It is shown in:

FIG. 1 the casting mold and strand shell stress as a function of the casting speed

FIG. 2 the interrelationships between the casting speed and

the slag film thickness

the strand shell temperature, shrinkage as well as trend shell thickness at the exit of the casting mold,

casting mold and strand shell stress as well as shrinkage,

temperature stress of the copper plates at the meniscus as well as service life of the copper plates relative to the recrystallization temperature of the cold-rolled copper plate.

The FIGS. 1 and 2 have already been described in detail as prior art and are provided for a better understanding of the following description which is not to be viewed as being obvious to a person skilled in the art and thus includes an inventive step.

FIG. 3. illustrates

a) a slab casting mold (1) with (1.1) and without pouring hopper and in regard to its conicity and adjustable narrow sides (1.2) as well as submerged exit nozzle (SEN)(1.5) and casting powder

b) the casting mold stress, expressed as MW/m2 for faces (WL) and (WF) as well as for the narrow sides (ND) and (NO) over the casting time and

c) the relationship of the heat flows from the faces to the narrow sides, expressed as NO/WL, NO/WF and ND/WL, NO/WF, which describe the course of the heat flows more simply and facilitate their correction over the conicity adjustment during casting.

FIG. 4 shows the casting situations A, B, C with the aid of

a) the heat flows, expressed as MW/m² or

b) the relationship of the heat flows ND/WF, ND/WL and NO/WF, NO/WL, which experience a correction by adjustment of the narrow sides in their conicity from the position 0 to the position 1.

FIG. 5 illustrates the temperature course of molten masses in the distributor over a casting time of one hour.

FIG. 6 illustrates the casting window defined by the steel temperature in the distributor and the casting speed with exemplary temperature courses of different molten masses.

FIG. 7 illustrates the data acquisition and the control circuit in the area of the continuous casting plant with the input of limits for the control and regulation of the narrow side conicities and the maximum casting speed as a function of the steel temperature in the distributor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 3 is comprised of the partial Figures a), b), and c). FIG. 3a) illustrates schematically a slab or bloom casting mold (1), comprised of two individual narrow sides (1.2), which are provided at the operating side (1.2.1) (NO) and drive side (1.2.2) (ND) with adjusting. cylinders (1.2.3), and two faces (1.3), respectively, the backside (1.3.1) (WF), and the loose side (1.3.2) (WL).

The casting mold (1) furthermore can advantageously be provided with a pouring hopper (1.1). The liquid steel (1.4) is introduced through the submerged exit nozzle (1.5) below the bath level (1.7.2) in the casting mold when using a casting powder (1.6) with formation of casting slag (1.6.1) and a casting slag film between the casting mold (1) and the strand shell (1.7.1), which is provided for lubrication and heat flow control.

FIGS. 3b) and c) show the specific course of heat flow in MW/m² of the faces WF, WL (1.3.2) and the narrow sides NO (1.2.1), NO (1.2.2) in the normal, uneventful casting process, wherein the casting time from the beginning to the time tx at which the steel is within temperature equilibrium. The narrow side flows must have over the conicity adjustment of the narrow sides a ratio to the faces of <1 which must be maintained constant over the casting time.

Different slag films formed across the strand circumference, especially between the faces and the narrow sides, different casting speeds, different steel temperatures, non-uniform flow conditions in the left and the right half of the casting mold, a deflection of the slab from the strand center axis in the casting direction can cause deviations in regard to the specific heat dissipation.

These deviations are illustrated in FIG. 4 with the aid of three typical situations A, B and C (FIG. 4) by means of the specific heat flows, expressed as MW/m² in FIG. 4b) and as a heat flow ratio narrow side/faces (N/W) in FIG. 4c).

In the situation A, the heat flow of the narrow side deviates at the drive side (ND) (1.2.2) from that of the narrow side at the thickness side (NO) (1.2.1) by a heat flow that is too small. With a greater adjustment of the conicity at the narrow side from position 0 to position 1, the heat flow is adjusted to that of the narrow side (NO).

In the situation B, the heat flows of both narrow sides are too great in comparison to the faces. By reducing the conicity adjustment of both narrow sides from the position 0 to the position 1, the heat flows are brought into the correct ratio relative to the faces.

In the situation C, the heat flows of the narrow sides are too small and can be adjusted to the correct value relative to the faces by a simultaneous enlargement of the narrow side conicity from the position 0 to the position 1.

FIG. 5 represents the temperature course of numerous molten masses over a time period of approximately 1 hour in the distributor. It can be seen that, for example, in these ladles with a molten mass contents of approximately 180 t the steel temperature drops by approximately 5° C./hour. This drop of the steel temperature in the distributor can be kept relatively small and depends substantially on

the residence time of the steel in the distributor, i.e., the casting output and

the insulation of the distributor.

The absolute temperature with which the steel flows into the distributor is predetermined by the continuous casting operation, is adjusted by the steel mill and depends on, for example,

ladle transport times,

ladle age and

ladle lining, which result often in deviations from the nominal temperature because of an uncontrolled operation process.

FIG. 6 represents the casting window defined by the steel temperature in the distributor and the maximum possible casting speed.

The casting window (4) is defined by an upper (3.0) and a lower (3.1) temperature limit. Moreover, in addition to the steel temperature in the casting mold (3.3), the area of the liquids temperature (3.4) of, for example, low-carbon steel qualities, is illustrated. The steel temperature in the casting mold increases for a constant steel temperature in the distributor with

greater distributor volume,

improved distributor insulation,

use of magneto-electro brake in the casting mold.

The FIG. 6 represents three molten masses with different distributor temperatures and thus different maximum possible casting speeds, but, for example, identical temperature loss of 5° C./hour.

In detail, these three situation in the casting window (4) are as follows. In the case (4.1), the steel temperature at the start of casting is 1,570° C. and makes possible a maximum casting speed (1.8) of 4.0 m/min., and after 1 hour casting time at the end of the ladle casting time the steel temperature of 1,565° C. allows for a maximum casting speed of 4.5 m/min.

In the case (4.2), the steel temperature in the distributor at the start of casting of the melt is 1,560° C. and at the end of casting 1,555° C. which makes possible a maximum casting speed of 5.0 m/min. and of 5.85 m/min. at the end of casting.

In the case (4.3), the temperature is 1,550° C. and makes possible a casting speed of 7.2 m/min. and at the end of casting, with a temperature of 1,545° C., a casting speed of >8 m/min. The speed of a maximum of 8 m/min. can be adjusted when reaching a temperature of approximately 1,548° C.

FIG. 7 illustrates the configuration of a semi-automation or a full automation/autopilot for casting in a high speed plant.

The device is comprised of a steel ladle (5), a distributor (6) with a stopper or slide closure (6.1) as well as a discontinuous or continuous temperature measurement in the distributor, a continuous casting plant with oscillating casting mold (1) and adjustable narrow sides (12) as well as removal rollers (6.3) which are driven by a motor (6.3.1) and which remove the strand at a controlled casting speed (1.8).

The following data acquisition is required for a full automation/autopilot:

temperature measurement of the steel in the distributor (6.2) in ° C.;

stopper movement or slide movement (6.1.1) in dy/dt;

heat flow measurement of the faces (7) in MW/m^(2.)

heat flow measurement of the narrow sides (8) in MW/m^(2;)

stopper movement

movement of the meniscus (9) in dx/dt; and

actual casting speed (1.8) in m/min.

These data are compared in an online computer (10) with the limits. With preconditions such as

a stopper movement of dy/dt of ±0, i.e., a “clean steel” which does not lead to a significant oxidic deposition within the SEN as well as to no stopper and SEN erosion,

a constant heat flow, within the faces at constant casting speed with a tolerance of a maximum of 0.1 MW/m² over the casting time and relative to one another,

a meniscus movement of a maximum of ±5 mm for a casting time of 60 seconds,

a heat flow ratio of the narrow sides to the faces of >0.9 and <0.4 the system interface (11) in the form of a “joystick” having the four functions

+/− casting speed and

+/− taper for the individual narrow sides and representing a semi-automation, can be switched to full automation or the status of autopilot in an operatively safe and thus breakout-free way (<0.5 percent).

The full automation corrects with the casting operation the conicity adjustments of each individual narrow side based on the heat flow ratios between the narrow sides and the faces outside of a narrow side/faces ratio of, for example, $0.8 > \frac{N}{W} > {0.5.}$

and automatically adjusts the maximum possible casting speed which is possible as a result of the steel temperature in the distributor and the provided equation.

The invention makes possible a reproducible operation of the continuous casting plant with maximum possible productivity and controlled strand quality while avoiding breakout.

List of Reference Numerals

(1) slab casting mold with oscillation

(1.1.) hopper

(1.2) narrow sides of casting mold

(1.2.1) narrow side of the operator side (NO)

(1.2.2) narrow side of the drive side (ND)

(1.2.3) adjusting cylinder

(1.3) faces

(1.3.1) face, fixed, or backside, WF

(1.3.2) face loose side or backside, WL

(1.4) liquid steel

(1.5) submerged entry nozzle, SEN

(1.6) casting powder

(1.6.1.1) casting slag film between casting mold and strand shell

(1.7) strand

(1.7.1) strand shell

(1.7.2) meniscus

(1.8) casting speed, V_(C)

(1.8.1) casting time t., after which the steel temperature is in equilibrium with the distributor

(3) upper temperature limit

(3.1) lower temperature limit

(3.3) steel temperature in the casting mold

(3.4) area of the liquids temperature of “low carbon” steel qualities

(3.5) causes of an increase of the steel temperature in the casting mold at controlled temperature of the steel in the distributor inlet

(4) casting window with three molten masses of different temperatures in the distributor and identical temperature loss of 5° C./hour in the casting window of steel temperature/casting speed

(4.1) situation 1 with a molten mass which results in a steel temperature in the distributor of 1,570° C. at the start of casting and 1,565° C. at the end of casting and allows for a casting speed of 4.0 and a maximum of 4.5 m/min.

(4.2) situation 2 with a molten mass which results in a steel temperature in the distributor of 1,560° C. at the beginning of casting and 1,560° C. at the end of casting and allows a casting speed of 5.0 and a maximum of 5.85 m/min

(4.3) situation 3 with the molten mass results in a steel temperature in the distributor of 1,500° C. at the start of casting and 1,545° C. at the end of casting and allows a casting speed of 7.0 and >8.0 m/min

(5) steel ladle

(6) distributor

(6.1) stopper or slide closure

(6.1.1) stopper or slide movement

(6.2) discontinuous or continuous temperature measurement of the steel in the distributor

(6.3) driven removal rollers

(6.3.1) drive motor

(7) heat flow measurement in MW/m² of the faces

(7.1) faces of the backside, fixed side WF

(7.2) faces of the loose side, WL

(8) heat flow measurement in MW/m2 of the narrow sides

(8.1) heat flow measurement of the operator side (NO)

(8.2) heat flow measurement of the drive side (ND)

(8.3) heat flow ratio narrow sides/faces

(8.3.1) heat flow ratio operator-narrow side/faces $\frac{\left( {{NO},{NO}} \right)}{\left( {{WL}\quad {WF}} \right)}$

(8.3.2) heat flow ratio drive narrow side/faces $\frac{\left( {{ND},{NO}} \right)}{\left( {{WL}\quad {WF}} \right)}$

(9) menisous movement dx/dt

(10) online computer

(10.1) limits

(11) system interface “joystick”

(11.1) full automation/autopilot status

(11.2) alarm for taking over in semi-automation 

What is claimed is:
 1. Method for operating a high-speed continuous casting plant for casting a metallic strand (1.7), in particular, a slab, with casting speeds of maximally 10 m/min., comprising an oscillating casting mold (1) which comprises oppositely positioned casting mold narrow sides having an operating side and a driving side (1.2.1, 1.2.2) and faces having a fixed side and a loose side (1.3.1, 1.3.2), in particular comprised of copper plates, wherein molten mass flows via a submerged exit nozzle (1.5) or a nozzle from a distributor (6) into the casting mold (1) and the distributor (6) comprises a movable stopper (6.1) or a slide closure for regulating the inflowing molten mass quantity, the method comprises the steps of: providing with or without casting powder (1.6), determining the actual casting state by measuring the following parameters during the casting process (online): meniscus level (9) of the molten mass in the casting mold (1) in mm/min., temperature (6.2) of the molten mass in the distributor (6) over the casting time, actual casting speed in m/min over the casting time, wherein furthermore the following is measured: stopper or slide closure movement (6.1.1) as a measure for the oxidic purity over the casting time, heat flow via the casting mold faces (WF; WL), heat flow via the casting mold narrow sides (NO; ND) in MW/m² over the casting time, and determining changes of the actual casting state based on the stopper or slide closure movement, the meniscus movement as well as the change of the heat flows via the casting mold faces over a predetermined time interval, and that, should the changes be within a predetermined nominal interval, operation is switched to automated casting operation, which includes comparison of the heat flow ratios of each individual narrow side or face for an angular adjustment of the narrow side conicity, in particular, the narrow side copper plate conicity, relative to one another for a correction in relation to the heat flows via the faces, and adjustment of a maximum permissible possible casting speed as a function of melting temperature in the distributor and the corresponding material to be cast or that, should the changes of at least one some of or all of the parameters for determining the casting state be outside of a predetermined nominal interval, a semi-automatic control of the angular adjustment of the casting mold narrow sides as well as the casting speed is maintained.
 2. Method according to claim 1, wherein, after switching has been carried out to an automated operation upon surpassing predetermined limits of changes of the casting parameters, an alarm (11.2) is triggered and operation is switched back to a semi-automated operation.
 3. Method according to claim 1, wherein the dependency of the melting temperature in the distributor and the maximum possible casting speed is set for each steel group, for example, “low carbon”, “medium carbon”, and “high carbon”.
 4. Method according to claim 1, wherein the heat flows per surface unit of the fixed side as well as the loose side of the casting mold faces (W) are measured and that the heat flows per surface unit of the operating side (NO) and drive side (ND) of the casting mold narrow sides are measured, that the changes of the respectively measured values are determined over a predetermined casting time interval, and, should the changes of at least some of the recorded values be within a predetermined limit interval, switching to an automated operation is carried out, wherein the limit interval is defined by: the change of the stopper movement is maximally ±2 mm/time unit, the change of the meniscus level is maximally ±5 mm/time unit, the change of the heat flows of the casting mold faces is maximally ±0.10 MW/m² absolute and relative to one another, that the heat flow ratio of the narrow sides to the faces is as follows 0.9>NO/W, ND/W>0.4 after completion of switching to automated operation, regulating the angular adjustments of the narrow sides by means of controlling the adjusting cylinder so that the ratio of the heat flows of the narrow sides over the faces is within the following limit interval 0.8>NO/W, ND/W>0.6, measuring the actual melting temperature in the distributor, controlling the maximum permissible casting speed as a function of the melting temperature and the alloy composition.
 5. Method according to claim 4, wherein the correction of the angular adjustment of the narrow sides is carried out automatically in steps of 0.1 mm/adjusting action.
 6. Method according to claim 4, wherein, in addition to the alloy composition, the casting powder is also used as a parameter in the control of the maximum permissible casting speed. 